Utilization of Plant Architecture Genes in Soybean to Positively Impact Adaptation to High Yield Environments

Jeong-Hwa Kim; Andrew Scaboo; Vincent Pantalone; Zenglu Li; Kristin Bilyeu

doi:10.3389/fpls.2022.891587

Utilization of Plant Architecture Genes in Soybean to Positively Impact Adaptation to High Yield Environments

Front Plant Sci. 2022 May 24:13:891587. doi: 10.3389/fpls.2022.891587. eCollection 2022.

Authors

Jeong-Hwa Kim¹, Andrew Scaboo¹, Vincent Pantalone², Zenglu Li³, Kristin Bilyeu⁴

Affiliations

¹ Division of Plant Science and Technology, University of Missouri, Columbia, MO, United States.
² Department of Plant Sciences, University of Tennessee, Knoxville, TN, United States.
³ Department of Crop and Soil Sciences, University of Georgia, Athens, GA, United States.
⁴ Plant Genetics Research Unit, United States Department of Agriculture-Agricultural Research Service, University of Missouri, Columbia, MO, United States.

Abstract

Optimization of plant architecture by modifying stem termination and timing of flowering and maturity of soybean is a promising strategy to improve its adaptability to specific production environments. Therefore, it is important to choose a proper stem termination type and to understand morphological differences between each stem termination type under various environmental conditions. Variations in abruptness of stem termination have been generally classified into three classical genetic types, indeterminate (Dt1), determinate (dt1), and semi-determinate (Dt2). However, an additional stem termination type, termed tall determinate, and its genetic symbol, dt1-t, were introduced about 25 years ago. The tall determinate soybean lines show delayed cessation of apical stem growth and about 50% taller plant heights than the typical determinate soybeans, even though the genetic control of the tall determinate phenotype was found to be allelic to dt1. Despite the potential agronomic merits of the alternative stem termination type, knowledge about the tall determinate soybean remains limited. We clarified the molecular basis of the tall determinate stem termination type and examined potential agronomic merits of the alternative stem type under three different production environments in the US. Sequence analysis of the classical tall determinate soybean lines revealed that the dt1-t allele responsible for tall determinate stem architecture is caused by two of the identified independent missense alleles of dt1, dt1-t1 (R130K), and dt1-t2 (R62S). Also, from the comparison among soybean accessions belonging to each of the genotype categories for stem termination types, soybean accessions with tall determinate alleles were found to have a high discrepancy rate in phenotyping. Newly developed tall determinate late-maturing soybean germplasm lines had taller plant heights and a greater number of nodes with a similar stem diameter and similar pod density at the apical stem compared to typical determinate soybeans having dt1 (R166W) alleles in Southern environments in the US. The phenotype of increased pod-bearing nodes with lodging resistance has the potential to improve yield, especially grown in high yield environments. This study suggests an alternative strategy to remodel the shape of soybean plants, which can possibly lead to yield improvement through the modification of soybean plant architecture.

Keywords: agronomic traits; plant architecture; southern environments; soybean; stem termination types.